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Rapid Analysis of Bisphenol A and Its Analogs in Food Packaging Products by Paper Spray Ionization Mass Spectrometry Shuo Chen, Quanying Chang, Kai Yin, Qunying He, Yongxiu Deng, Bo Chen, Chengbin Liu, Ying Wang, and Liping Wang J. Agric. Food Chem., Just Accepted Manuscript • Publication Date (Web): 24 May 2017 Downloaded from http://pubs.acs.org on May 25, 2017

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Journal of Agricultural and Food Chemistry

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Rapid Analysis of Bisphenol A and Its Analogs in Food Packaging Products by Paper

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Spray Ionization Mass Spectrometry

3 4

Shuo Chen,†,‡ Quanying Chang, § Kai Yin,† Qunying He,† Yongxiu Deng,† Bo Chen,‡,*

5

Chengbin Liu,† Ying Wang, §,* and Liping Wang#

6 7



8

and Chemical Engineering, Hunan University, Changsha 410082, China

9



State Key Laboratory of Chemo/Biosensing and Chemometrics, College of Chemistry

Key Laboratory of Phytochemical R&D of Hunan Province and Key Laboratory of

10

Chemical Biology & Traditional Chinese Medicine Research, Ministry of Education, Hu-

11

nan Normal University, Changsha 410081, China

12

§

College of Finance and Statistics, Hunan University, Changsha 410082, China

13

#

Hunan Analysis and Testing Center, Changsha 410004, China



Corresponding authors. E-mail address: [email protected]. Tel & Fax: +86-731-

88872531

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ABSTRACT In this study, a paper spray ionization mass spectrometric (PS-MS) method was de-

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veloped for the rapid in situ screening and simultaneous quantitative analysis of bi-

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sphenol A and its analogs, i.e., bisphenol S, bisphenol F, and bisphenol AF, in food pack-

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aging products. At the optimal PS-MS conditions, the calibration curves of bisphenols in

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the range of 1-100 µg/mL were linear. The correlation coefficients were higher than

20

0.998, the LODs of the target compounds were 0.1-0.3 µg/mL. After a simple treatment

21

by dichloromethane on the surface, the samples were analyzed by PS-MS in situ for rapid

22

screening without a traditional sample pretreatment procedure, such as powdering, ex-

23

traction and enrichment steps. The analytical time of the PS-MS method was less than 1

24

min. In comparison with conventional HPLC-MS/MS, it was demonstrated that PS-MS

25

was a more effective high-throughput screening and quantitative analysis method.

26 27

Keywords: bisphenol A, bisphenol S, bisphenol F, bisphenol AF, paper spray ionization

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mass spectrometry, food packaging products.

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Journal of Agricultural and Food Chemistry

INTRODUCTION

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Bisphenol A (Figure 1) is widely employed to produce polycarbonate plastics and

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epoxy resins, which are used in many plastic food packaging products, including baby

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bottles, drinking containers, and snack packaging.1-6 However, there are a number of

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studies that confirm the considerable damage of bisphenol A on human health, including

34

neural disorders and behavioral dysfunction and reproductive damage etc.7-13 In 2015, a

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document on risk assessment was published in the Food Contact Materials, Enzymes,

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Flavourings and Processing Aids (CEF) Panel's “Scientific opinion on the risks to public

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health related to the presence of bisphenol A in foodstuff”. The CEF Panel established a

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temporary Tolerable Daily Intake (t-TDI) of 4 µg/kg bw/d by aplying a total uncertainty

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factor of 150.14

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In addition, bisphenol A analogs, such as bisphenol S, bisphenol F, and bisphenol

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AF (Figure 1), have similar physicochemical properties to 1. Therefore, the analogs are

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rendered as candidates for replacement 1 in industrial applications.9 Unfortunately, this

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similarity is also expected to result in harmful toxicological profiles. Kitamura et al.15

44

demonstrated that 1 and 2 were potent anti-androgen compounds. Castro et al.16 found

45

potential adverse effects of 3 and 2 in the developing brain of mammals. Kinch et al.17

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demonstrated that 1 and 2 induce precocious hypothalamic neurogenesis at low-dose ex-

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posures. Additional harmful effects have been proven, including genotoxicity, DNA

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damage,18 oxidative stress etc.19 In 2016, Chen et al.20 reviewed the environmental occur-

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rence, human exposure and toxicity of bisphenol analogs other than 1. They showed that

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2, 3 and 4 may drive a new global contamination trend as 1 replacements.

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Because of their high sensitivity and selectivity, LC-MS and GC-MS are usually

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used to identify 1 and its analogs.21-23 However, sample pretreatment methods, such as

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liquid-liquid extraction,22 solid-phase extraction,23 or solid-phase micro extraction,24 for

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complex samples, e.g., urine, require considerable time and labor, and the analytical

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throughput of the methods is low. In addition, LC-MS is not easy to use for the rapid

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screening of 1 and its analogs in food packaging products because the separation is time

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consuming.

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Ambient mass spectrometry (AMS) is a new technology. It can directly analyze

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sample or sample surface without or with less sample pretreatment. After Cooks’ group

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presented desorption electrospray ionization (DESI),25 AMS has been developed rapidly

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because of its rapid, high-throughput merits.26-28 It is a potential high-throughput screen-

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ing method for hazardous ingredients. Now, more than 30 ambient ionization methods

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have been developed.29 Among different AMS techniques, paper spray MS (PS-MS) has

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unique advantages, e.g. in situ analysis and simple instrumental construction for ioniza-

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tion. In addition, PS-MS has good quantitation ability (18 MΩ) used for the experiments was purified by a Milli-Q System.

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The samples, including mineral water bottles, energy drink bottles, plastic cups, pa-

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per cups and baby bottles,. were purchased from Wal-Mart (Changsha, China). One baby

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bottle was an imported product produced by Philips Avent Corporation (UK).

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Apparatus

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A ZQ 2000 single-quad mass spectrometer with a scan speed range of 197 to 3980

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Da/s (Manchester, UK) was used to record the signal for PS-MS analysis. The resolution

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was as follows: the peaks at 1080.8 and 1081.8 from an infusion of β-cyclodextrin re-

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solved with a valley between them of no more than 10% of the average height of the two

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peaks. An XYZR (three-dimensional plus angle adjustment) moving platform was made

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in-house and used to accurately control location of the spray tip.

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LC-MS/MS analysis was accomplished using an LCMS-8050 liquid chromatograph

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mass spectrometer (Shimadzu, Kyoto, Japan) coupled with two LC-20AD HPLC pumps,

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a SIL-20A autosampler, a DGU-20A3R degassing unit, and a CTO-20A column oven.

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System control and data processing were performed with the Labsolutions chromatog-

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raphy workstation, version 5.75 (Shimadzu).

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Rapid Screening Analysis by Direct Sample Spray-MS

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Samples were cut into triangle-like shapes with dimensions of 4 mm at the base and

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10 mm in height for paper spray. Before direct sample spray-MS analysis, the plastic

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piece was soaked in dichloromethane for 1 min. After being dried under nitrogen, the

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sample was fixed on the XYZR moving platform by an alligator clamp; the triangular tip

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was held 5 mm from the ion cone of the MS. Ten microliters of methanol was used as a

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spray solvent and dropped on the sample surface, then -2.5 kV was applied to form the

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sample spray ionization. The spray process lasted for 10-15 s. For paper product analysis,

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the method was the same but without soaking in dichloromethane.

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The MS parameters for the working negative ion mode of the ZQ 2000 for PS-MS

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analysis were as follows: cone voltages: -40 V; extractor voltage: -1 V; ion energy: 0.5;

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source temperature: 100 °C; RF lens voltage: -0.5 V; cone gas (N2): 5 L/h.

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Rapid Quantitative Analysis by PS-MS

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For rapid quantitative analysis by PS-MS, triangular filter paper (base: 6 mm;

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height: 12 mm) was employed as PS substrates. The triangular paper was cut by a CUT-

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OK DC 330 craft cutting plotter (Hefei CNC Equipment Co., Hefei, China). The sample

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volume for PS-MS analysis was 10 µL.

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Bisphenol A-d16 was used as I. S. at 10 µg/mL in a series of standard solutions us-

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ing methanol as solvent. The calibration curves of 1, 2, 3, and 4 were constructed with

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ratios of abundance of target ions (m/z of 1, 2, 3, 4 was 227, 249, 199, 335, respectively)

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to I.S. (m/z: 241) vs. the concentrations of 1, 2, 3, 4, respectively. The concentration

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range was 1-100 µg/mL. The limits of detection (LOD) were determined by injecting di-

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luted standards. The least concentrated standard yielding a signal/noise ratio >3 was con-

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sidered as the LOD.

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For polymer samples for analyses, the sample treatment method was similar to the

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FDA method.41 The detailed procedures are as follows: 0.10 of cut sample was mixed

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with 2 mL of methylene chloride in a flask. The flask was placed in an ultrasonic water

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bath for 30 min to dissolve the sample. Eight milliliters of methanol was added in the

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flask to precipitate the polymer completely. The polymer precipitate was allowed to settle

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for 10 min. Five milliliters of the sample filter liquor was dried by N2 stream. The residue

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was redissolved in 0.2 mL of methanol including 10 µg/mL of bisphenol A-d16.

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For paper products, the sample, cut into small pieces, was extracted by shaking with

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methanol. After filtering, 1 mL of the sample solution was dried by N2. The residual 1

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and its analogs were redissolved in 1 mL of methanol including 10 µg/mL of bisphenol

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A-d16.40

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LC-MS/MS Analysis.

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The samples were also analyzed by LC-MS/MS to investigate the accuracy of PS-

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MS. The sample pretreatment methods were similar to those of the PS-MS analysis. LC-

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MS/MS conditions were similar to those in the literature.22

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The column used was a 150 mm × 2.0 mm i.d., 5 µm, Shim-pack VP-ODS (Shimad-

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zu). The mobile phase was methanol:water, with 0.1% ammonium hydroxide (v/v). A

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gradient elution was adopted starting with 30% MeOH and reaching 90% MeOH in 3

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min, maintaining this percentage for 2 min and finally to 30% MeOH and held for 4 min

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prior to the next injection. The column temperature was kept at 50 °C. The mobile phase

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flow-rate was set at 0.4 mL/min, and the injection volume was 10 µL. MS conditions

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were as follows: MS scan range was m/z 100−500 using electrospray ionization (ESI)

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working in negative ion mode. Interface, DL, and heat block temperatures were 300, 250,

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and 400 °C, respectively. Nitrogen was used as a sheath gas, ion sweep gas and auxiliary

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gas at flow rates of 40, 10 and 55 arbitrary units, respectively. Argon used as a collision-

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induced dissociation (CID) gas was approximately 1.5 mTorr, the collision energy was

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3.5 V. The deprotonated molecule [M-H]- was used as the precursor ion. Quantitation

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was made in MRM mode. The following channels were utilized: 227>211 for 1; 249>108

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for 2; 241>223 for bisphenol A-d16; 199>93 for 3 and 335>265 for 4. All collision ener-

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gies (CE) were 25 V.

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RESULTS AND DISCUSSION

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Optimization of PS-MS Conditions

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To study the effect of different solvents on the PS-MS response, different solvents,

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i.e., water, methanol (MeOH), ethanol (EtOH), ethyl ether (EtOAc), benzene and their

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mixtures, were investigated using 1 as a model target on a filter paper matrix. Ten micro-

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liters of 1 standard solution in methanol (10 µg/mL) was dropped on triangular filter pa-

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per. After being dried by N2, spray solvent was dropped on the paper, and voltage was

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then applied to finish PS-MS. The results showed that the MS signal of 1 was too low

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when ethyl ether and water were used as solvents, and the result with benzene as the sol-

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vent was lower than methanol and ethanol. Methanol was the best solvent for PS-MS

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analysis of 1. The responses in all mixed solvents were lower than that in methanol.

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The selection of spray volume plays an important part in PS-MS detection. The ef-

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fect of different spray volumes of methanol, i.e., 5, 10, 15 and 20 µL, on the MS signal of

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1 at the same concentration (10 µg/mL) was investigated at a -2.5 kV spray voltage using

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filter paper as the matrix. The results showed that the response intensity of 1 was mini-

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mized when the spray volume was 5 µL. When the spray volume was 10 µL, the response

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intensity was good, but when it was 15 µL, the response started to drop off. At 20 µL, the

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response was close to the minimum. When the volume was too small (5 µL), the for-

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mation of stable Taylor cone jets are difficult. However, a larger volume will form multi-

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ple Taylor cone jets, reducing the sensitivity.30 Ten milliliters of spray volume was se-

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lected for subsequent experiments.

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The spray voltage of PS-MS must be chosen carefully in the negative ion mode. Op-

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timization of the spray voltage for the detection of bisphenols was completed. The effects

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of different spray voltages on PS-MS responses showed that -2.5 kV was optimal for the

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detection of bisphenols. When the voltage was low, ionization efficiency was limited. A

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higher voltage will also affect the sensitivity because the onset voltage of electrical dis-

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charge is always lower than that of electrospray ionization, seriously degrading ESI per-

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formance.

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Because the temperature of the MS source of ZQ 2000 also affects the sensitivity

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due to the formation of solvent adduct ion and its effect on ion transmission, different

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source temperatures, i.e., 50 °C, 70 °C, 85 °C, 100 °C, 120 °C, 150 °C, were investigated.

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The results demonstrated that 100 °C gave the best PS-MS response at [M-H]- of 1. Be-

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cause there was a small spray solvent volume, a higher source temperature was adverse

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during ion transmission due to thermal degradation. In addition, ion transmission effi-

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ciency will also be reduced when the temperature is low. Therefore, 100 °C was selected

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for subsequent experiments.

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Pretreatment of the Plastic Surface for in situ PS-MS Analysis for Rapid Screening

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For in situ PS-MS analysis, different sample matrixes, such as plastic and paper

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products, significantly affected the sensitivity. For paper products, such as paper cups,

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bisphenols in the thin coating can be easily extracted by methanol and spray ionization.

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However, plastic was difficult to analyze by PS-MS only using methanol as the spray

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solvent. Its surface was smooth (Figure 2A) and methanol cannot effectively extract bi-

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sphenols from the matrix. To effectively analyze plastic products in situ by PS-MS, we

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used dichloromethane to destroy the smooth surface and extract bisphenols to the surface.

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The SEM images of untreated and treated surfaces of a baby bottle containing 1 are pre-

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sented in Figure 2, which shows that the surface rugosity is completely different. After

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treatment, the specific surface area increased dramatically. In addition, bisphenols can

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also be extracted to the surface, increasing the detection sensitivity. To further optimize

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the experimental conditions, in situ PS-MS responses of 1 were compared over different

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treatment times, such as 30 s, 1 min, 3 min, 5 min, 10 min. The results showed that the

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response of 1 min treatment was the highest. With increased treatment time, the response

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decreased. With 5 min of treatment, the response reduced substantially, and at 10 min

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there was no PS-MS response. When treated with dichloromethane, there are two proce-

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dures: 1. The smooth surface is destroyed and more 1 is exposed on the surface; and 2. 1

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on the surface diffuses into the solvent. Competition between the two procedures affects

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the amount of 1 on the surface. When the treatment time was long, almost all the 1 on the

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surface diffused into the solvent. Therefore, there was no PS-MS response.

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Quantitative Analysis by PS-MS

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A typical PS-MS mass spectra of mixed standards is shown in Figure 3. The calibra-

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tion curves of bisphenols are shown in Figure 4. The chromatograms of standards at dif-

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ferent concentrations and I.S. are shown in Figure 5.

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In the range of 1-100 µg/mL for 1, 2, 3, and 4, the correlation coefficients are greater

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than 0.998. The limits of detection (LODs) were 0.1, 0.1, 0.3, 0.1 µg/mL for 1, 2, 3, 4,

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respectively. Using baby bottle extract without bisphenols as the matrix, the LODs were

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almost same with that of the diluted standards, i.e., 0.1, 0.2 0.3 0.2 µg/mL for 1, 2, 3, 4,

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respectively. The comparison of typical samples analyzed by PS-MS and HPLC-MS/MS

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are given in Table 1.

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The quantitative results of PS-MS are similar to those of HPLC-MS/MS, suggesting

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that PS-MS quantitative analysis is useful for the rapid determination of bisphenols in

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food packaging products. However, the repeatability by PS-MS (RSD: 8.4%), especially

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for plastic products, is lower than that of HPLC-MS/MS (RSD: 3.5%). Nonvolatile plas-

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tic matrix effects may be a major factor affecting effective ionization. Therefore, more

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effective sample pretreatment is necessary for accurate quantitation by PS-MS.

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Application of PS-MS for the Analysis of Bisphenols

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Forty-two samples were analyzed after in situ rapid screening and then quantitated

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by PS-MS. The results are listed in Table 2. A typical PS-MS spectrum of a sample is

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shown in Figure 6.

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The results demonstrate that 1 are still major chemical contaminants in food packag-

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ing products, including paper products and plastic products. 2 likewise appeared in prod-

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ucts. 3 and 4 were not been detected.

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The increasing awareness regarding safety to bisphenol A and its analogs requires

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methods capable of handling numerous samples in a short time frame. From the results

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obtained in this study, the PS-MS method presented is capable of rapidly screening for 1,

241

3, 2 and 4 at a rate of approximately 1 min/sample. Moreover, it has been demonstrated

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that quantitation of bisphenols in food packaging products by PS-MS using deuterated

243

internal standards is feasible. The results of sample analyses showed that the food pack-

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aging products still use 1 in raw material in China, and as a replacement for 1, 2 has en-

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tered the market in China.

246 247

ABBREVIATIONS

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PS-MS, paper spray ionization mass spectrometric; BPA, bisphenol A; BPS, bisphenol S;

249

BPF, bisphenol F; BPAF, bisphenol AF; EFSA, European Food Safety Authority; CEF,

250

Food Contact Materials, Enzymes, Flavourings and Processing Aids; t-TDI, temporary

251

Tolerable Daily Intake; AMS, ambient mass spectrometry; DESI, desorption electrospray

252

ionization; DCBI, desorption corona beam ionization.

253 254

SUPPORTING INFORMATION*

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Figure SI-1. Picture of the XYZR moving platfor

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Figure SI-2. PS-MS response of 1 with different spray solvent

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Figure SI-3. PS-MS response in different spray volume

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Figure SI-4. PS-MS response at different spray voltage

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Figure SI-5. PS-MS response of 1 at different source temperatures

260

Figure SI-6. In-situ PS-MS response of 1 with different treating times

261 262 263

*This material is available free of charge via the internet at http://pubs.acs.org.

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AUTHOR INFORMATION

265 266

Alternate corresponding author:

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*: Ying Wang. Address: College of Finance and Statistics, Hunan University, Changsha

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410082, China. Tel & Fax: +86-731-88822286. E-mail: [email protected]

269 270

ACKNOWLEDGMENTS The authors would like to thank local health inspection institute for samples collec-

271 272

tion.

273 274 275

CONFLICT OF INTEREST The authors declare no competing financial interest.

276 277

FUNDING

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The authors thank the National Natural Science Foundation of China (21575040,

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71673078, 21275049) and the construction program of the key discipline of Hunan Prov-

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ince for financial support. The project was also supported by the foundation for innova-

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tive research groups of the Hunan Natural Science Foundation of China (2015JC1001).

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sphenol analogues other than BPA: environmental occurrence, human exposure, and

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toxicity—a review. Environ. Sci. Technol. 2016, 50, 5438–5453.

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bisphenol A at ultra-trace levels by liquid chromatography and tandem mass spec-

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trometry. Anal. Bioanal. Chem. 2016, 408, 1009–1013.

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A and six analogues (S, F, Z, P, AF, AP) determination in urine samples based on dis-

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trometry. Talanta 2016, 154, 511–519. 23. Schmidt, L.; Muller, J.; Goen, T. Simultaneous monitoring of seven phenolic me-

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tabolites of endocrine disrupting compounds (EDC) in human urine using gas chro-

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evaluation of molecularly imprinted solid-phase microextraction fibers for selective

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extraction of bisphenol A in complex samples. J. Chromatogr. A 2009, 1216, 5647–

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25. Takáts, Z.; Wiseman, J. M.; Gologan, B.; Cooks, R. G. Mass spectrometry sampling

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30. Lin, C. H.; Liao, W. C.; Chen, H. K.; Kuo, T. Y. Paper spray-MS for bioanalysis. Bioanalysis 2014, 6, 199–208.

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plex mixtures using mass spectrometry. Angew. Chem., Int. Ed. 2010, 49, 877–880.

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simulating liquids. J. Agric. Food Chem. 1997, 45, 3541–3544.

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Journal of Agricultural and Food Chemistry

407

FIGURE CAPTIONS

408

Figure 1. Chemical structures of bisphenol A and analogues.

409

(M1=228.29, M2=250.27, M3=200.24, M4=336.23)

410

Figure 2. SEM images of sample surface. (A) Sample without treatment, (B) Sample

411

treated for 1 min

412

Figure 3. PS-MS spectra of 1 and its analogues (10 µg/mL)

413

m/z: 3, 199; 1, 227; bisphenol A-d16, 241; 2, 249; 4, 335

414

Figure 4. Calibration curves of 1, 2, 3, 4 in the range of 1-100 µg/mL using bisphenol A-

415

d16 as I.S.

416

Figure 5. Chromatogram of 1, 2, 3, 4 and bisphenol A-d16 by PS-MS

417

Figure 6. PS-MS spectra of baby bottle with bisphenol A-d16

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Table 1. Comparison Results Between PS-MS and HPLC-MS/MS PS-MS (mg/kg) (n=5)

HPLC-MS/MS (mg/kg) (n=5)

sample 1

2

1

2

Paper cup

12.2±0.7

ND

11.8±0.3

ND*

Baby bottle 1

ND

7.9±0.3

ND

8.5±0.2

Baby bottle 2

34.6±2.5

ND

36.2±1.3

ND

food packaging paper

67.2±5.7

ND

69.9±2.4

ND

food packaging film

32.3±1.7

ND

33.7±0.9

ND

*ND: Not detected.

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Journal of Agricultural and Food Chemistry

Table 2. Sample Analysis Results by PS-MS PS-MS quantitative results (n=5) (µg/g) sample 1

2

1

2

1

PC 1

positive

negative

12.2±0.7

ND

2

PC 2

positive

negative

22.7±1.2

ND

3

PC 3

positive

negative

14.5±0.9

ND

4

PC 4

positive

negative

18.7±1.2

ND

5

PC 5

positive

negative

25.6±1.4

ND

6

PlC 1

positive

negative

20.6±1.3

ND

7

PlC 2

positive

negative

42.7±3.0

ND

8

PlC 3

positive

negative

27.8±1.3

ND

9

PlC 4

positive

negative

32.2±0.9

ND

10

BB 1

negative

positive

ND

7.9±0.3

11

BB 2

positive

negative

34.6±2.5

ND

12

BB 3

negative

negative

ND

ND

13

BB 4

positive

negative

30.1±3.0

ND

14

MWB 1

positive

negative

67.2±5.7

ND

15

MWB 2

positive

negative

43.4±3.9

ND

16

MWB 3

positive

negative

35.1±1.9

ND

17

MWB 4

positive

negative

10.3±0.7

ND

18

EDB 1

positive

negative

22.2±1.3

ND

19

EDB 2

positive

negative

10.7±1.0

ND

20

EDB 3

positive

negative

34.1±1.6

ND

21

EDB 4

positive

negative

9.2±0.8

ND

22

FPF 1

positive

negative

32.3±1.7

ND

23

FPF 2

positive

negative

34.7±2.9

ND

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24

FPF 3

positive

negative

18.9±1.1

ND

25

FPF 4

positive

negative

24.3±1.1

ND

26

FPF 5

positive

negative

13.2±0.9

ND

27

IPC 1

positive

negative

42.7±2.7

ND

28

IPC 2

positive

negative

40.3±2.9

ND

29

IPC 3

positive

negative

35.1±1.4

ND

30

IPC 4

positive

negative

37.9±2.1

ND

31

IPC 5

positive

negative

46.8±2.7

ND

32

IPC 6

positive

negative

27.3±2.0

ND

33

FPP 1

positive

negative

67.2±5.7

ND

34

FPP 2

positive

negative

43.4±3.9

ND

35

FPP 3

positive

negative

46.1±2.7

ND

36

FPP 4

positive

negative

27.5±1.8

ND

37

FPP 5

positive

negative

38.1±2.7

ND

38

FPP 6

positive

negative

21.4±1.5

ND

39

FPP 7

positive

negative

17.8±1.5

ND

40

DS 1

positive

negative

51.9±3.7

ND

41

DS 2

positive

negative

45.2±2.6

ND

42

DS 3

positive

negative

47.8±3.2

ND

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Journal of Agricultural and Food Chemistry

O S O HO

OH

HO

OH 2. Bisphenol S

1. Bisphenol A

F

HO

OH

F

FFF

HO

3. Bisphenol F

F

OH

4. Bisphenol AF Figure 1.

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Figure 2.

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Journal of Agricultural and Food Chemistry

Figure 3.

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Journal of Agricultural and Food Chemistry

1

Page 28 of 31

3

2

4

Figure 4.

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Journal of Agricultural and Food Chemistry

Figure 5

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Figure 6

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Journal of Agricultural and Food Chemistry

ToC 254x190mm (96 x 96 DPI)

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